ch_11 cell communication
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Transcript ch_11 cell communication
Cell to Cell
Communication
AP Biology
Chapter 11
Introduction
• Cell-to-cell communication is absolutely
essential for multicellular organisms and is
also important for many unicellular
organisms.
– Cells must communicate to coordinate their
activities.
• Biologists have discovered some universal
mechanisms of cellular regulation, involving
the same small set of cell-signaling
mechanisms.
• Cells may receive a variety of signals,
chemical signals, electromagnetic signals,
and mechanical signals.
• Signal-transduction pathway: The process by which
a signal on a cell’s surface is converted into a specific
cellular response.
Talking to cells, both near
and far…
• Multicellular organisms can also release
signaling molecules that target other cells.
– Some transmitting cells release local
regulators that influence cells in the local
vicinity.
– In synaptic signaling, a nerve cell produces a
neurotransmitter that diffuses to a single cell
that is almost touching the sender.
– Plants and animals use hormones to signal at
greater distances.
– Cells may communicate by direct contact.
How do Cells
Communicate?
• The process must involve three stages.
– In reception, a chemical signal binds to a
cellular protein, typically at the cell’s surface.
– In transduction, binding leads to a change in
the receptor that triggers a series of changes
along a signal-transduction pathway.
– In response,
the transduced
signal triggers
a specific
cellular
activity.
Signal molecules and
Receptor Proteins
• A cell targeted by a particular chemical signal
has a receptor protein that recognizes the
signal molecule.
– Recognition occurs when the signal binds to a specific
site on the receptor because it is complementary in
shape.
• When ligands (small molecules that bind
specifically to a larger molecule) attach to the
receptor protein, the receptor typically
undergoes a change in shape.
– This may activate the receptor so that it can interact
with other molecules.
– For other receptors this leads to the collection of
receptors.
Signal Molecules
• Most signal molecules are water-soluble
and too large to pass through the plasma
membrane.
• They influence cell activities by binding
to receptor proteins on the plasma
membrane.
– Binding leads to change in the shape or the
receptor or to aggregation of receptors.
– These trigger changes in the intracellular
environment.
• Three major types of receptors are Gprotein-linked receptors, tyrosine-kinase
receptors, and ion-channel receptors.
G-Protein-Linked Receptor
• A G-protein-linked receptor consists of a
receptor protein associated with a Gprotein on the cytoplasmic side.
– The receptor consists of seven alpha helices
spanning the membrane.
– Effective signal
molecules include
yeast mating
factors,
epinephrine,
other hormones,
and
neurotransmitters.
• The G protein acts as an on-off
switch.
– If GDP is bound, the G protein is inactive.
– If GTP is bound, the G protein is active.
• The G-protein system cycles between on
and off.
– When a G-protein-linked receptor is activated
by binding with an extracellular signal molecule,
the receptor binds to an inactive G protein in
membrane.
– This leads the G protein to substitute GTP for
GDP.
– The G protein then binds with another
membrane protein, often an enzyme, altering its
activity and leading
to a cellular
response.
• G-protein receptor systems are extremely
widespread and diverse in their functions.
– In addition to functions already mentioned,
they play an important role during embryonic
development and sensory systems.
• Similarities among G proteins and Gprotein-linked receptors suggest that this
signaling system evolved very early.
• Several human diseases are the results of
activities, including bacterial infections,
that interfere with G-protein function.
Tyrosine-kinase
Receptors
• Tyrosine-kinase receptor is
effective when the cell needs to
regulate and coordinate a variety of
activities and trigger several signal
pathways at once.
• A tyrosine-kinase is an enzyme that
transfers phosphate groups from
ATP to the amino acid tyrosine on a
protein.
• Individual tyrosine-kinase
receptors consists of several
parts:
– an extracellular signal-binding sites,
– a single alpha helix spanning the
membrane, and
– an intracellular
tail with several
tyrosines.
• When ligands bind to two receptors
polypeptides, the polypeptides bind,
forming a dimer.
• This activates the tyrosine-kinase
section of both.
• These add
phosphates to the
tyrosine tails of
the other
polypeptide.
• The fully-activated receptor proteins
initiate a variety of specific relay proteins
that bind to specific phosphorylated
tyrosine molecules.
– One tyrosine-kinase receptor dimer may
activate ten or more different intracellular
proteins simultaneously.
• These activated relay
proteins trigger many
different transduction
pathways and
responses.
Ligand-gated
Ion Channels
• Ligand-gated ion channels are
protein pores that open or close
in response to a chemical signal.
– This allows or blocks ion flow, such
as Na+ or Ca2+.
– Binding by a ligand to the
extracellular side changes the
protein’s shape and opens the
channel.
– Ion flow changes the
concentration inside the cell.
– When the ligand dissociates, the
channel closes.
– Very important in the nervous
system
The Others…
• Other signal receptors are dissolved in the
cytosol or nucleus of target cells.
• The signals pass through the plasma
membrane.
• These chemical messengers include the
hydrophobic steroid and thyroid hormones
of animals.
• Also in this group is nitric oxide (NO), a
gas whose small size allows it to slide
between membrane phospholipids.
Testosterone
• Testosterone, like other
hormones, travels through
the blood and enters cells
throughout the body.
• In the cytosol, they bind and
activate receptor proteins.
• These activated proteins
enter the nucleus and turn on
genes that control male sex
characteristics.
Turning Genes On
• These activated proteins act as
transcription factors.
– Transcription factors control which
genes are turned on - that is, which
genes are transcribed into messenger
RNA (mRNA).
• The mRNA molecules leave the nucleus and
carry information that directs the synthesis
(translation) of specific proteins at the
ribosome.
Transduction
• The transduction stage of signaling is
usually a multistep pathway.
• These pathways often greatly amplify the
signal.
– If some molecules in a pathway transmit a
signal to multiple molecules of the next
component, the result can be large numbers of
activated molecules at the end of the pathway.
• A small number of signal molecules can
produce a large cellular response.
• Also, multistep pathways provide more
opportunities for coordination and
regulation than do simpler systems.
Signal Transduction
Pathways
• Signal transduction pathways act like
falling dominoes.
– The signal-activated receptor activates
another protein, which activates another and
so on, until the protein that produces the final
cellular response is activated.
• The original signal molecule is not passed
along the pathway, it may not even enter
the cell.
– Its information is passed on.
– At each step the signal is transduced into a
different form, often by a
conformational change in a protein.
Phosphorylation (adding
on Phosphates)
• The phosphorylation of proteins by a specific
enzyme (a protein kinase) is a mechanism for
regulating protein activity.
– Most protein kinases act on other substrate proteins,
unlike the tyrosine kinases that act on themselves.
• Most phosphorylation occurs at either serine or
threonine amino acids in the substrate protein.
• Many of the relay molecules in a signal-transduction
pathway are protein kinases that lead to a
“phosphorylation cascade”.
• Each protein phosphorylation leads to a shape
change because of the interaction between
the phosphate group and charged or polar
amino acids.
Phosphorylation
• Phosphorylation of a protein typically converts it
from an inactive form to an active form.
– The reverse (inactivation) is possible too for some
proteins.
• A single cell may have hundreds of different
protein kinases, each specific for a different
substrate protein.
– Fully 1% of our genes may code for protein kinases.
• Abnormal activity of protein kinases can cause
abnormal cell growth and contribute to the
development of cancer.
Protein Phosphatase
• The responsibility for turning off a signaltransduction pathway belongs to protein
phosphatases.
– These enzymes rapidly remove phosphate groups from
proteins.
– The activity of a protein regulated by phosphorylation
depends on the balance of active kinase molecules and
active phosphatase molecules.
• When an extracellular signal molecule is absent,
active phosphatase molecules predominate, and
the signaling pathway and cellular response are
shut down.
Second Messengers
• Many signaling pathways involve small,
nonprotein, water-soluble molecules or
ions, called second messengers.
– These molecules rapidly diffuse throughout
the cell.
• Second messengers participate in
pathways initiated by both G-proteinlinked receptors and tyrosine-kinase
receptors.
– Two of the most important are cyclic AMP and
Ca2+.
Pathway involving cAMP
as a secondary
messenger.
Pathway using Ca2+ as
a secondary
messenger.
The Response
• Ultimately, a signal-transduction
pathway leads to the regulation of
one or more cellular activities.
– This may be a change in an ion channel or
a change in cell metabolism.
– For example, epinephrine helps regulate
cellular energy metabolism by activating
enzymes that catalyze the breakdown of
glycogen.
• Some signaling
pathways do not
regulate the activity
of enzymes but the
synthesis of enzymes
or other proteins.
• Activated receptors
may act as
transcription factors
that turn specific
genes on or off in the
nucleus.
Benefits of Multiple
Steps
• Signaling pathways with multiple steps
have two benefits.
– They amplify the response to a signal.
– They contribute to the specificity of the
response.
• At each catalytic step in a cascade, the
number of activated products is much
greater than in the preceding step.
– A small number of epinephrine molecules can
lead to the release of hundreds of millions of
glucose molecules.
Differences
• Various types of cells may receive
the same signal but produce very
different responses.
• These differences result from a
basic observation:
– Different kinds of cells have different
collections of proteins.
• The response of a particular cell to
a signal depends on its particular
collection of receptor proteins, relay
proteins, and proteins needed to
carry out the response.
Scaffolding
• Rather than relying on diffusion of large
relay molecules like proteins, many signal
pathways are linked together physically by
scaffolding proteins.
– Scaffolding proteins may themselves be relay
proteins to which several other relay proteins
attach.
– This hardwiring
enhances the
speed and
accuracy of
signal transfer
between cells.
Relay Proteins
• The importance of relay proteins that
serve as branch or intersection points is
underscored when these proteins are
defective or missing.
– The inherited disorder, Wiskott-Aldrich syndrome
(WAS), is due to the absence of a single relay protein.
– It leads to abnormal bleeding, eczema, and a
predisposition to infections and leukemia.
– The WAS protein interacts with the microfilaments of
the cytoskeleton and several signaling pathways,
including those that regulate immune cell proliferation.
– When the WAS protein is absent, the cytoskeleton is
not properly organized and signaling pathways are
disrupted.
Deactivation
• As important as activating mechanisms are
inactivating mechanisms.
– For a cell to remain alert and capable of responding
to incoming signals, each molecular change in its
signaling pathways must last only a short time.
– If signaling pathway components become locked
into one state, the proper function of the cell can
be disrupted.
– Binding of signal molecules to receptors must be
reversible, allowing the receptors to return to
their inactive state when the signal is released.
– Similarly, activated signals (cAMP and
phosphorylated proteins) must be inactivated by
appropriate enzymes to prepare the cell
for a fresh signal.